/*
 * consumer_sdl.c -- A Simple DirectMedia Layer consumer
 * Copyright (C) 2017-2025 Meltytech, LLC
 *
 * This library is free software; you can redistribute it and/or
 * modify it under the terms of the GNU Lesser General Public
 * License as published by the Free Software Foundation; either
 * version 2.1 of the License, or (at your option) any later version.
 *
 * This library is distributed in the hope that it will be useful,
 * but WITHOUT ANY WARRANTY; without even the implied warranty of
 * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.  See the GNU
 * Lesser General Public License for more details.
 *
 * You should have received a copy of the GNU Lesser General Public
 * License along with this library; if not, write to the Free Software
 * Foundation, Inc., 51 Franklin Street, Fifth Floor, Boston, MA  02110-1301  USA
 */

#include "common.h"

#include <SDL.h>
#include <framework/mlt_consumer.h>
#include <framework/mlt_deque.h>
#include <framework/mlt_factory.h>
#include <framework/mlt_filter.h>
#include <framework/mlt_frame.h>
#include <framework/mlt_log.h>
#include <pthread.h>
#include <stdatomic.h>
#include <stdio.h>
#include <stdlib.h>
#include <string.h>
#include <sys/time.h>

#undef MLT_IMAGE_FORMAT // only yuv422 working currently

extern pthread_mutex_t mlt_sdl_mutex;

/** This classes definition.
*/

typedef struct consumer_sdl_s *consumer_sdl;

struct consumer_sdl_s
{
    struct mlt_consumer_s parent;
    mlt_properties properties;
    mlt_deque queue;
    pthread_t thread;
    int joined;
    atomic_int running;
    uint8_t audio_buffer[4096 * 10];
    int audio_avail;
    pthread_mutex_t audio_mutex;
    pthread_cond_t audio_cond;
    pthread_mutex_t video_mutex;
    pthread_cond_t video_cond;
    int window_width;
    int window_height;
    int previous_width;
    int previous_height;
    int width;
    int height;
    int out_channels;
    SDL_Window *sdl_window;
    SDL_Renderer *sdl_renderer;
    SDL_Texture *sdl_texture;
    SDL_Rect sdl_rect;
    uint8_t *buffer;
    int is_purge;
#ifdef _WIN32
    int no_quit_subsystem;
#endif
};

/** Forward references to static functions.
*/

static int consumer_start(mlt_consumer parent);
static int consumer_stop(mlt_consumer parent);
static int consumer_is_stopped(mlt_consumer parent);
static void consumer_purge(mlt_consumer parent);
static void consumer_close(mlt_consumer parent);
static void *consumer_thread(void *);
static int setup_sdl_video(consumer_sdl self);

/** This is what will be called by the factory - anything can be passed in
	via the argument, but keep it simple.
*/

mlt_consumer consumer_sdl2_init(mlt_profile profile,
                                mlt_service_type type,
                                const char *id,
                                char *arg)
{
    // Create the consumer object
    consumer_sdl self = calloc(1, sizeof(struct consumer_sdl_s));

    // If no malloc'd and consumer init ok
    if (self != NULL && mlt_consumer_init(&self->parent, self, profile) == 0) {
        // Create the queue
        self->queue = mlt_deque_init();

        // Get the parent consumer object
        mlt_consumer parent = &self->parent;

        // We have stuff to clean up, so override the close method
        parent->close = consumer_close;

        // get a handle on properties
        mlt_service service = MLT_CONSUMER_SERVICE(parent);
        self->properties = MLT_SERVICE_PROPERTIES(service);

        // Set the default volume
        mlt_properties_set_double(self->properties, "volume", 1.0);

        // This is the initialisation of the consumer
        pthread_mutex_init(&self->audio_mutex, NULL);
        pthread_cond_init(&self->audio_cond, NULL);
        pthread_mutex_init(&self->video_mutex, NULL);
        pthread_cond_init(&self->video_cond, NULL);

        // Default scaler (for now we'll use nearest)
        mlt_properties_set(self->properties, "rescale", "nearest");
        mlt_properties_set(self->properties, "consumer.deinterlacer", "onefield");
        mlt_properties_set_int(self->properties, "top_field_first", -1);

        // Default buffer for low latency
        mlt_properties_set_int(self->properties, "buffer", 1);

        // Default audio buffer
        mlt_properties_set_int(self->properties, "audio_buffer", 2048);

        // Default scrub audio
        mlt_properties_set_int(self->properties, "scrub_audio", 1);

        // Ensure we don't join on a non-running object
        self->joined = 1;

        // process actual param
        if (arg && sscanf(arg, "%dx%d", &self->width, &self->height)) {
            mlt_properties_set_int(self->properties, "resolution", 1);
        } else {
            self->width = mlt_properties_get_int(self->properties, "width");
            self->height = mlt_properties_get_int(self->properties, "height");
        }

        // Allow thread to be started/stopped
        parent->start = consumer_start;
        parent->stop = consumer_stop;
        parent->is_stopped = consumer_is_stopped;
        parent->purge = consumer_purge;

        // Register specific events
        mlt_events_register(self->properties, "consumer-sdl-event");

        // Return the consumer produced
        return parent;
    }

    // malloc or consumer init failed
    free(self);

    // Indicate failure
    return NULL;
}

int consumer_start(mlt_consumer parent)
{
    consumer_sdl self = parent->child;

    if (!self->running) {
        mlt_properties properties = MLT_CONSUMER_PROPERTIES(parent);
        int audio_off = mlt_properties_get_int(properties, "audio_off");
        char *output_display = mlt_properties_get(properties, "output_display");
        char *audio_driver = mlt_properties_get(properties, "audio_driver");
        char *video_driver = mlt_properties_get(properties, "video_driver");
        char *audio_device = mlt_properties_get(properties, "audio_device");

        consumer_stop(parent);

        self->running = 1;
        self->joined = 0;

        if (output_display != NULL)
            setenv("DISPLAY", output_display, 1);

        if (video_driver != NULL)
            setenv("SDL_VIDEODRIVER", video_driver, 1);

        if (audio_driver != NULL)
            setenv("SDL_AUDIODRIVER", audio_driver, 1);

        if (audio_device != NULL)
            setenv("AUDIODEV", audio_device, 1);

        if (!mlt_properties_get_int(self->properties, "resolution")) {
            if (mlt_properties_get_int(self->properties, "width") > 0)
                self->width = mlt_properties_get_int(self->properties, "width");
            if (mlt_properties_get_int(self->properties, "height") > 0)
                self->height = mlt_properties_get_int(self->properties, "height");
        }

        if (audio_off == 0)
            SDL_InitSubSystem(SDL_INIT_AUDIO);

        // Default window size
        if (mlt_properties_get_int(self->properties, "resolution")) {
            self->window_width = self->width;
            self->window_height = self->height;
        } else {
            double display_ratio = mlt_properties_get_double(self->properties, "display_ratio");
            self->window_width = (double) self->height * display_ratio + 0.5;
            self->window_height = self->height;
        }

        // Initialize SDL video if needed.
#ifdef __APPLE__
        if (setup_sdl_video(self))
            return 1;
#else
        if (!SDL_WasInit(SDL_INIT_VIDEO)) {
            pthread_mutex_lock(&mlt_sdl_mutex);
            int ret = SDL_Init(SDL_INIT_VIDEO);
            pthread_mutex_unlock(&mlt_sdl_mutex);
            if (ret < 0) {
                mlt_log_error(MLT_CONSUMER_SERVICE(&self->parent),
                              "Failed to initialize SDL: %s\n",
                              SDL_GetError());
                return 1;
            }
        }
#endif

        pthread_create(&self->thread, NULL, consumer_thread, self);
    }

    return 0;
}

int consumer_stop(mlt_consumer parent)
{
    // Get the actual object
    consumer_sdl self = parent->child;

    if (self->joined == 0) {
        // Kill the thread and clean up
        self->joined = 1;
        self->running = 0;

        if (!mlt_properties_get_int(MLT_CONSUMER_PROPERTIES(parent), "audio_off")) {
            pthread_mutex_lock(&self->audio_mutex);
            pthread_cond_broadcast(&self->audio_cond);
            pthread_mutex_unlock(&self->audio_mutex);
        }

#ifndef _WIN32
        if (self->thread)
#endif
            pthread_join(self->thread, NULL);

        // cleanup SDL
        pthread_mutex_lock(&mlt_sdl_mutex);
        if (self->sdl_texture)
            SDL_DestroyTexture(self->sdl_texture);
        self->sdl_texture = NULL;
        if (self->sdl_renderer)
            SDL_DestroyRenderer(self->sdl_renderer);
        self->sdl_renderer = NULL;
        if (self->sdl_window)
            SDL_DestroyWindow(self->sdl_window);
        self->sdl_window = NULL;
#ifdef _WIN32
        if (!self->no_quit_subsystem)
#endif
            if (!mlt_properties_get_int(MLT_CONSUMER_PROPERTIES(parent), "audio_off"))
                SDL_QuitSubSystem(SDL_INIT_AUDIO);
        if (mlt_properties_get_int(MLT_CONSUMER_PROPERTIES(parent), "sdl_started") == 0)
            SDL_Quit();
        pthread_mutex_unlock(&mlt_sdl_mutex);
    }

    return 0;
}

int consumer_is_stopped(mlt_consumer parent)
{
    consumer_sdl self = parent->child;
    return !self->running;
}

void consumer_purge(mlt_consumer parent)
{
    consumer_sdl self = parent->child;
    if (self->running) {
        pthread_mutex_lock(&self->video_mutex);
        while (mlt_deque_count(self->queue))
            mlt_frame_close(mlt_deque_pop_back(self->queue));
        self->is_purge = 1;
        pthread_cond_broadcast(&self->video_cond);
        pthread_mutex_unlock(&self->video_mutex);
    }
}

static void sdl_fill_audio(void *udata, uint8_t *stream, int len)
{
    consumer_sdl self = udata;

    // Get the volume
    double volume = mlt_properties_get_double(self->properties, "volume");

    // Wipe the stream first
    memset(stream, 0, len);

    pthread_mutex_lock(&self->audio_mutex);

    // Block until audio received
    while (self->running && len > self->audio_avail)
        pthread_cond_wait(&self->audio_cond, &self->audio_mutex);

    if (self->audio_avail >= len) {
        // Place in the audio buffer
        if (volume != 1.0)
            SDL_MixAudio(stream,
                         self->audio_buffer,
                         len,
                         (int) ((float) SDL_MIX_MAXVOLUME * volume));
        else
            memcpy(stream, self->audio_buffer, len);

        // Remove len from the audio available
        self->audio_avail -= len;

        // Remove the samples
        memmove(self->audio_buffer, self->audio_buffer + len, self->audio_avail);
    } else {
        // Mix the audio
        SDL_MixAudio(stream, self->audio_buffer, len, (int) ((float) SDL_MIX_MAXVOLUME * volume));

        // No audio left
        self->audio_avail = 0;
    }

    pthread_cond_broadcast(&self->audio_cond);
    pthread_mutex_unlock(&self->audio_mutex);
}

static int consumer_play_audio(consumer_sdl self, mlt_frame frame, int init_audio, int *duration)
{
    // Get the properties of self consumer
    mlt_properties properties = self->properties;
    mlt_audio_format afmt = mlt_audio_s16;

    // Set the preferred params of the test card signal
    int channels = mlt_properties_get_int(properties, "channels");
    int frequency = mlt_properties_get_int(properties, "frequency");
    int scrub = mlt_properties_get_int(properties, "scrub_audio");
    static int counter = 0;

    int samples = mlt_audio_calculate_frame_samples(mlt_properties_get_double(self->properties,
                                                                              "fps"),
                                                    frequency,
                                                    counter++);
    int16_t *pcm;
    mlt_frame_get_audio(frame, (void **) &pcm, &afmt, &frequency, &channels, &samples);
    *duration = ((samples * 1000) / frequency);
    pcm += mlt_properties_get_int(properties, "audio_offset");

    if (mlt_properties_get_int(properties, "audio_off")) {
        init_audio = 1;
        return init_audio;
    }

    if (init_audio == 1) {
        SDL_AudioSpec request;
        SDL_AudioSpec got;
        SDL_AudioDeviceID dev;
        int audio_buffer = mlt_properties_get_int(properties, "audio_buffer");

        // specify audio format
        memset(&request, 0, sizeof(SDL_AudioSpec));
        request.freq = frequency;
        request.format = AUDIO_S16SYS;
        request.channels = mlt_properties_get_int(properties, "channels");
        request.samples = audio_buffer;
        request.callback = sdl_fill_audio;
        request.userdata = (void *) self;

        dev = sdl2_open_audio(&request, &got);
        if (dev == 0) {
            mlt_log_error(MLT_CONSUMER_SERVICE(self), "SDL failed to open audio\n");
            init_audio = 2;
        } else {
            if (got.channels != request.channels) {
                mlt_log_info(MLT_CONSUMER_SERVICE(self),
                             "Unable to output %d channels. Change to %d\n",
                             request.channels,
                             got.channels);
            }
            mlt_log_info(MLT_CONSUMER_SERVICE(self),
                         "Audio Opened: driver=%s channels=%d frequency=%d\n",
                         SDL_GetCurrentAudioDriver(),
                         got.channels,
                         got.freq);
            SDL_PauseAudioDevice(dev, 0);
            init_audio = 0;
            self->out_channels = got.channels;
        }
    }

    if (init_audio == 0) {
        mlt_properties properties = MLT_FRAME_PROPERTIES(frame);
        int samples_copied = 0;
        int dst_stride = self->out_channels * sizeof(*pcm);

        pthread_mutex_lock(&self->audio_mutex);

        while (self->running && samples_copied < samples) {
            int sample_space = (sizeof(self->audio_buffer) - self->audio_avail) / dst_stride;
            while (self->running && sample_space == 0) {
                struct timeval now;
                struct timespec tm;

                gettimeofday(&now, NULL);
                tm.tv_sec = now.tv_sec + 1;
                tm.tv_nsec = now.tv_usec * 1000;
                pthread_cond_timedwait(&self->audio_cond, &self->audio_mutex, &tm);
                sample_space = (sizeof(self->audio_buffer) - self->audio_avail) / dst_stride;

                if (sample_space == 0 && self->running) {
                    mlt_log_warning(MLT_CONSUMER_SERVICE(&self->parent), "audio timed out\n");
                    pthread_mutex_unlock(&self->audio_mutex);
#ifdef _WIN32
                    self->no_quit_subsystem = 1;
#endif
                    return 1;
                }
            }
            if (self->running) {
                int samples_to_copy = samples - samples_copied;
                if (samples_to_copy > sample_space) {
                    samples_to_copy = sample_space;
                }
                int dst_bytes = samples_to_copy * dst_stride;

                if (scrub || mlt_properties_get_double(properties, "_speed") == 1) {
                    if (channels == self->out_channels) {
                        memcpy(&self->audio_buffer[self->audio_avail], pcm, dst_bytes);
                        pcm += samples_to_copy * channels;
                    } else {
                        int16_t *dest = (int16_t *) &self->audio_buffer[self->audio_avail];
                        int i = samples_to_copy + 1;
                        while (--i) {
                            memcpy(dest, pcm, dst_stride);
                            pcm += channels;
                            dest += self->out_channels;
                        }
                    }
                } else {
                    memset(&self->audio_buffer[self->audio_avail], 0, dst_bytes);
                    pcm += samples_to_copy * channels;
                }
                self->audio_avail += dst_bytes;
                samples_copied += samples_to_copy;
            }
            pthread_cond_broadcast(&self->audio_cond);
        }
        pthread_mutex_unlock(&self->audio_mutex);
    }

    return init_audio;
}

static int setup_sdl_video(consumer_sdl self)
{
    int error = 0;
    int sdl_flags = SDL_WINDOW_RESIZABLE;
    int texture_format = SDL_PIXELFORMAT_YUY2;

    // Skip this if video is disabled.
    int video_off = mlt_properties_get_int(self->properties, "video_off");
    int preview_off = mlt_properties_get_int(self->properties, "preview_off");
    uintptr_t window_id = mlt_properties_get_int(self->properties, "window_id");

    if (video_off || preview_off)
        return error;

#ifdef __APPLE__
    if (!SDL_WasInit(SDL_INIT_VIDEO)) {
        pthread_mutex_lock(&mlt_sdl_mutex);
        int ret = SDL_Init(SDL_INIT_VIDEO);
        pthread_mutex_unlock(&mlt_sdl_mutex);
        if (ret < 0) {
            mlt_log_error(MLT_CONSUMER_SERVICE(&self->parent),
                          "Failed to initialize SDL: %s\n",
                          SDL_GetError());
            return -1;
        }
    }
#endif

#ifdef MLT_IMAGE_FORMAT
    int image_format = mlt_properties_get_int(self->properties, "mlt_image_format");

    if (image_format)
        switch (image_format) {
        case mlt_image_rgb:
            texture_format = SDL_PIXELFORMAT_RGB24;
            break;
        case mlt_image_rgba:
            texture_format = SDL_PIXELFORMAT_ABGR8888;
            break;
        case mlt_image_yuv420p:
            texture_format = SDL_PIXELFORMAT_IYUV;
            break;
        case mlt_image_yuv422:
            texture_format = SDL_PIXELFORMAT_YUY2;
            break;
        default:
            mlt_log_error(MLT_CONSUMER_SERVICE(&self->parent),
                          "Invalid image format %s\n",
                          mlt_image_format_name(image_format));
            return -1;
        }
#endif

    if (mlt_properties_get_int(self->properties, "fullscreen")) {
        self->window_width = self->width;
        self->window_height = self->height;
        sdl_flags |= SDL_WINDOW_FULLSCREEN_DESKTOP;
        SDL_ShowCursor(SDL_DISABLE);
    }

    pthread_mutex_lock(&mlt_sdl_mutex);

    if (window_id) {
        self->sdl_window = SDL_CreateWindowFrom((void *) window_id);
        SDL_SetWindowResizable(self->sdl_window, SDL_TRUE);
    } else {
        self->sdl_window = SDL_CreateWindow("MLT",
                                            SDL_WINDOWPOS_UNDEFINED,
                                            SDL_WINDOWPOS_UNDEFINED,
                                            self->window_width,
                                            self->window_height,
                                            sdl_flags);
    }

    self->sdl_renderer = SDL_CreateRenderer(self->sdl_window, -1, SDL_RENDERER_ACCELERATED);
    if (self->sdl_renderer) {
        // Get texture width and height from the profile.
        int width = mlt_properties_get_int(self->properties, "width");
        int height = mlt_properties_get_int(self->properties, "height");
        self->sdl_texture = SDL_CreateTexture(self->sdl_renderer,
                                              texture_format,
                                              SDL_TEXTUREACCESS_STREAMING,
                                              width,
                                              height);
        if (self->sdl_texture) {
            SDL_SetRenderDrawColor(self->sdl_renderer, 0, 0, 0, 255);
        } else {
            mlt_log_error(MLT_CONSUMER_SERVICE(&self->parent),
                          "Failed to create SDL texture: %s\n",
                          SDL_GetError());
            error = -1;
        }
    } else {
        mlt_log_error(MLT_CONSUMER_SERVICE(&self->parent),
                      "Failed to create SDL renderer: %s\n",
                      SDL_GetError());
        error = -1;
    }
    pthread_mutex_unlock(&mlt_sdl_mutex);

    return error;
}

static int consumer_play_video(consumer_sdl self, mlt_frame frame)
{
    // Get the properties of this consumer
    mlt_properties properties = self->properties;

#ifdef MLT_IMAGE_FORMAT
    mlt_image_format vfmt = mlt_properties_get_int(properties, "mlt_image_format");
#else
    mlt_image_format vfmt = mlt_image_yuv422;
#endif
    int width = self->width, height = self->height;
    uint8_t *image;

    int video_off = mlt_properties_get_int(properties, "video_off");
    int preview_off = mlt_properties_get_int(properties, "preview_off");
    int display_off = video_off | preview_off;
    uintptr_t window_id = mlt_properties_get_int(self->properties, "window_id");

    if (self->running && !display_off) {
        if (!self->sdl_window) {
            int error = setup_sdl_video(self);
            if (error)
                return error;
        }

        // Get the image, width and height
        mlt_frame_get_image(frame, &image, &vfmt, &width, &height, 0);

        if (self->running) {
            // Determine window's new display aspect ratio, and resize if it's an existing window
            int w = mlt_properties_get_int(properties, "window_width");
            int h = mlt_properties_get_int(properties, "window_height");
            int width_changed = (w && w != self->window_width);
            int height_changed = (h && h != self->window_height);

            if (width_changed || height_changed) {
                if (width_changed) {
                    self->window_width = w;
                }
                if (height_changed) {
                    self->window_height = h;
                }
                if (window_id) {
                    SDL_SetWindowSize(self->sdl_window, self->window_width, self->window_height);
                }
            }

            double this_aspect = (double) self->window_width / self->window_height;

            // Get the display aspect ratio
            double display_ratio = mlt_properties_get_double(properties, "display_ratio");

            // Determine frame's display aspect ratio
            double frame_aspect = mlt_frame_get_aspect_ratio(frame) * width / height;

            // Store the width and height received
            self->width = width;
            self->height = height;

            // If using hardware scaler
            if (mlt_properties_get(properties, "rescale") != NULL
                && !strcmp(mlt_properties_get(properties, "rescale"), "none")) {
                // Use hardware scaler to normalize display aspect ratio
                self->sdl_rect.w = frame_aspect / this_aspect * self->window_width;
                self->sdl_rect.h = self->window_height;
                if (self->sdl_rect.w > self->window_width) {
                    self->sdl_rect.w = self->window_width;
                    self->sdl_rect.h = this_aspect / frame_aspect * self->window_height;
                }
            }
            // Special case optimisation to negate odd effect of sample aspect ratio
            // not corresponding exactly with image resolution.
            else if ((int) (this_aspect * 1000) == (int) (display_ratio * 1000)) {
                self->sdl_rect.w = self->window_width;
                self->sdl_rect.h = self->window_height;
            }
            // Use hardware scaler to normalize sample aspect ratio
            else if (self->window_height * display_ratio > self->window_width) {
                self->sdl_rect.w = self->window_width;
                self->sdl_rect.h = self->window_width / display_ratio;
            } else {
                self->sdl_rect.w = self->window_height * display_ratio;
                self->sdl_rect.h = self->window_height;
            }

            self->sdl_rect.x = (self->window_width - self->sdl_rect.w) / 2;
            self->sdl_rect.y = (self->window_height - self->sdl_rect.h) / 2;
            self->sdl_rect.x -= self->sdl_rect.x % 2;

            mlt_properties_set_int(self->properties, "rect_x", self->sdl_rect.x);
            mlt_properties_set_int(self->properties, "rect_y", self->sdl_rect.y);
            mlt_properties_set_int(self->properties, "rect_w", self->sdl_rect.w);
            mlt_properties_set_int(self->properties, "rect_h", self->sdl_rect.h);
        }

        if (self->running && image) {
            unsigned char *planes[4];
            int strides[4];

            mlt_image_format_planes(vfmt, width, height, image, planes, strides);
            if (strides[1]) {
                SDL_UpdateYUVTexture(self->sdl_texture,
                                     NULL,
                                     planes[0],
                                     strides[0],
                                     planes[1],
                                     strides[1],
                                     planes[2],
                                     strides[2]);
            } else {
                SDL_UpdateTexture(self->sdl_texture, NULL, planes[0], strides[0]);
            }
            SDL_RenderClear(self->sdl_renderer);
            SDL_RenderCopy(self->sdl_renderer, self->sdl_texture, NULL, &self->sdl_rect);
            SDL_RenderPresent(self->sdl_renderer);
        }

        mlt_events_fire(properties, "consumer-frame-show", mlt_event_data_from_frame(frame));
    } else if (self->running) {
        if (!video_off) {
            mlt_image_format preview_format = mlt_properties_get_int(properties, "preview_format");
            vfmt = preview_format == mlt_image_none ? mlt_image_rgba : preview_format;
            mlt_frame_get_image(frame, &image, &vfmt, &width, &height, 0);
        }
        mlt_events_fire(properties, "consumer-frame-show", mlt_event_data_from_frame(frame));
    }

    return 0;
}

static void *video_thread(void *arg)
{
    // Identify the arg
    consumer_sdl self = arg;

    // Obtain time of thread start
    struct timeval now;
    int64_t start = 0;
    int64_t elapsed = 0;
    struct timespec tm;
    mlt_frame next = NULL;
    mlt_properties properties = NULL;
    double speed = 0;

    // Get real time flag
    int real_time = mlt_properties_get_int(self->properties, "real_time");

    // Determine start time
    gettimeofday(&now, NULL);
    start = (int64_t) now.tv_sec * 1000000 + now.tv_usec;

    while (self->running) {
        // Pop the next frame
        pthread_mutex_lock(&self->video_mutex);
        next = mlt_deque_pop_front(self->queue);
        while (next == NULL && self->running) {
            pthread_cond_wait(&self->video_cond, &self->video_mutex);
            next = mlt_deque_pop_front(self->queue);
        }
        pthread_mutex_unlock(&self->video_mutex);

        if (!self->running || next == NULL) {
            if (self->running) {
                mlt_log_warning(
                    MLT_CONSUMER_SERVICE(&self->parent),
                    "video thread got a null frame even though the consumer is still running!\n");
            }
            break;
        }

        // Get the properties
        properties = MLT_FRAME_PROPERTIES(next);

        // Get the speed of the frame
        speed = mlt_properties_get_double(properties, "_speed");

        // Get the current time
        gettimeofday(&now, NULL);

        // Get the elapsed time
        elapsed = ((int64_t) now.tv_sec * 1000000 + now.tv_usec) - start;

        // See if we have to delay the display of the current frame
        if (mlt_properties_get_int(properties, "rendered") == 1 && self->running) {
            // Obtain the scheduled playout time
            int64_t scheduled = mlt_properties_get_int(properties, "playtime");

            // Determine the difference between the elapsed time and the scheduled playout time
            int64_t difference = scheduled - elapsed;

            // Smooth playback a bit
            if (real_time && (difference > 20000 && speed == 1.0)) {
                tm.tv_sec = difference / 1000000;
                tm.tv_nsec = (difference % 1000000) * 500;
                nanosleep(&tm, NULL);
            }

            // Show current frame if not too old
            if (!real_time
                || (difference > -10000 || speed != 1.0 || mlt_deque_count(self->queue) < 2))
                consumer_play_video(self, next);

            // If the queue is empty, recalculate start to allow build up again
            if (real_time && (mlt_deque_count(self->queue) == 0 && speed == 1.0)) {
                gettimeofday(&now, NULL);
                start = ((int64_t) now.tv_sec * 1000000 + now.tv_usec) - scheduled + 20000;
            }
        } else {
            static int dropped = 0;
            mlt_log_info(MLT_CONSUMER_SERVICE(&self->parent), "dropped video frame %d\n", ++dropped);
        }

        // This frame can now be closed
        mlt_frame_close(next);
        next = NULL;
    }

    if (next != NULL)
        mlt_frame_close(next);

    mlt_consumer_stopped(&self->parent);

    return NULL;
}

static void *consumer_thread(void *arg)
{
    // Identify the arg
    consumer_sdl self = arg;

    // Get the consumer
    mlt_consumer consumer = &self->parent;

    // Convenience functionality
    int terminate_on_pause = mlt_properties_get_int(MLT_CONSUMER_PROPERTIES(consumer),
                                                    "terminate_on_pause");
    int terminated = 0;

    // Video thread
    pthread_t thread;

    // internal initialization
    int init_audio = 1;
    int init_video = 1;
    mlt_frame frame = NULL;
    int duration = 0;
    int64_t playtime = 0;
    struct timespec tm = {0, 100000};

    // Loop until told not to
    while (self->running) {
        // Get a frame from the attached producer
        frame = !terminated ? mlt_consumer_rt_frame(consumer) : NULL;

        // Check for termination
        if (terminate_on_pause && frame)
            terminated = mlt_properties_get_double(MLT_FRAME_PROPERTIES(frame), "_speed") == 0.0;

        // Ensure that we have a frame
        if (frame) {
            // Play audio
            init_audio = consumer_play_audio(self, frame, init_audio, &duration);

            if (init_video) {
                // Create the video thread
                pthread_create(&thread, NULL, video_thread, self);

                // Video doesn't need to be initialised any more
                init_video = 0;
            }

            // Set playtime for this frame
            mlt_properties_set_int(MLT_FRAME_PROPERTIES(frame), "playtime", playtime);

            while (self->running && mlt_deque_count(self->queue) > 15)
                nanosleep(&tm, NULL);

            // Push this frame to the back of the queue
            pthread_mutex_lock(&self->video_mutex);
            if (self->is_purge) {
                mlt_frame_close(frame);
                frame = NULL;
                self->is_purge = 0;
            } else {
                mlt_deque_push_back(self->queue, frame);
                pthread_cond_broadcast(&self->video_cond);
            }
            pthread_mutex_unlock(&self->video_mutex);

            // Calculate the next playtime
            playtime += (duration * 1000);
        } else if (terminated) {
            if (init_video || mlt_deque_count(self->queue) == 0)
                break;
            else
                nanosleep(&tm, NULL);
        }
    }

    self->running = 0;

    // Unblock sdl_preview
    if (mlt_properties_get_int(MLT_CONSUMER_PROPERTIES(consumer), "put_mode")
        && mlt_properties_get_int(MLT_CONSUMER_PROPERTIES(consumer), "put_pending")) {
        frame = mlt_consumer_get_frame(consumer);
        if (frame)
            mlt_frame_close(frame);
        frame = NULL;
    }

    // Kill the video thread
    if (init_video == 0) {
        pthread_mutex_lock(&self->video_mutex);
        pthread_cond_broadcast(&self->video_cond);
        pthread_mutex_unlock(&self->video_mutex);
        pthread_join(thread, NULL);
    }

    while (mlt_deque_count(self->queue))
        mlt_frame_close(mlt_deque_pop_back(self->queue));

    pthread_mutex_lock(&self->audio_mutex);
    self->audio_avail = 0;
    pthread_mutex_unlock(&self->audio_mutex);

    return NULL;
}

static void consumer_close(mlt_consumer parent)
{
    // Get the actual object
    consumer_sdl self = parent->child;

    // Stop the consumer
    ///mlt_consumer_stop( parent );

    // Now clean up the rest
    mlt_consumer_close(parent);

    // Close the queue
    mlt_deque_close(self->queue);

    // Destroy mutexes
    pthread_mutex_destroy(&self->audio_mutex);
    pthread_cond_destroy(&self->audio_cond);

    // Finally clean up this
    free(self);
}
